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GaAs, pHEMT, MMIC,1/2 W, 20 GHz to 44 GHz, Power Amplifier
Data Sheet ADPA7002CHIP
Rev. C Document Feedback Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners.
FEATURES Output P1dB: 28 dBm (typical at 34 GHz to 44 GHz) PSAT: 30 dBm (typical at 20 GHz to 34 GHz) Gain: 15 dB (typical at 34 GHz to 44 GHz) IP3: 40 dBm (typical) Supply voltage: 5 V at 600 mA Die size: 2.75 mm × 1.805 mm × 0.1 mm
APPLICATIONS Military and space Test instrumentation
FUNCTIONAL BLOCK DIAGRAM
RFOUTRFIN
ADPA7002CHIP
GND
VDET
VREF
VDD1BVGG1B
VGG1A VDD1A VDD2A VDD3A
VDD2B VDD3B
1723
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1
Figure 1.
GENERAL DESCRIPTION The ADPA7002CHIP is a gallium arsenide (GaAs), monolithic microwave integrated circuit (MMIC), pseudomorphic high electron mobility transistor (pHEMT), distributed power amplifier that operates from 20 GHz to 44 GHz. The amplifier provides 15 dB of small signal gain, 28 dBm output power at 1 dB gain compression (P1dB), and a typical output third-order intercept (IP3) of 40 dBm. The amplifier requires 600 mA from
a 5 V supply on VDD1B, VDD2B, and VDD3B. The ADPA7002CHIP also features inputs/outputs (I/Os) that are internally matched to 50 Ω, and facilitates integration into multichip modules (MCMs). All data is taken with the on substrate chip connected via two wire bonds that are 0.025 mm (1 mil) wide and 0.31 mm (12 mils) long.
TABLE OF CONTENTS Features .............................................................................................. 1 Applications ....................................................................................... 1 Functional Block Diagram .............................................................. 1 General Description ......................................................................... 1 Revision History ............................................................................... 2 Specifications ..................................................................................... 3
20 GHz to 34 GHz Frequency Range ......................................... 3 34 GHz to 44 GHz Frequency Range ......................................... 3
Pin Configuration and Function Descriptions ............................. 5 Interface Schematics..................................................................... 6
Theory of Operation ...................................................................... 15 ADPA7002CHIP Assembly and Circuit Diagrams ............... 16 Alternate Assembly Diagram .................................................... 17 Biasing Procedures ..................................................................... 18 Biasing the ADPA7002CHIP with the HMC980LP4E .............. 18 Mounting and Bonding Techniques for Millimeter Wave GaAs MMICs .............................................................................. 22
REVISION HISTORY 4/2020—Rev. B to Rev. C Changes to Figure 1 and General Description Section ............... 1 Changes to Figure 2 and Table 5 ..................................................... 5 Changes to Figure 7 and Figure 9 ................................................... 6 Changes to Constant Drain Current (IDD) Operation Section ........ 14 Changes to Figure 54 and Figure 55 ............................................. 16 Changes to Bias Procedures Section and Biasing the ADPA7002CHIP with the HMC980LP4E Section ...................... 18 Changes to Figure 59 and Figure 60 ............................................. 19 Changes to HMC980LP4E Bias Sequence Section and Constant Drain Current Biasing vs. Constant Gate Voltage Biasing Section .............................................................................................. 20 Deleted Testing the HMC980LP4E Section ................................ 21 Changes to Figure 63 to Figure 66 ................................................ 21 Updated Outline Dimensions ....................................................... 23 2/2020—Rev. A to Rev. B Changes to Figure 1 .......................................................................... 1 Changes to Supply Parameter, Table 1 and Table 2 ...................... 3 Change to Table 3 ............................................................................. 4
Changes to Figure 2 and Table 5 ...................................................... 5 Changes to Typical Performance Characteristics Section ........... 7 Changes to Figure 54 and Figure 55 ............................................ 16 Changes to Biasing Procedures Section, Biasing the ADPA7002CHIP with the HMC980LP4E, and Application Circuit Setup Section ..................................................................... 18 Changes to Constant Drain Current Biasing vs. Constant Gate Voltage Biasing Section .................................................................. 20 7/2019—Rev. 0 to Rev. A Added Thermal Resistance Section and Table 4; Renumbered Sequentially ........................................................................................ 4 Changes to Figure 10 ......................................................................... 7 2/2019—Revision 0: Initial Version
SPECIFICATIONS 20 GHz TO 34 GHz FREQUENCY RANGE TA = 25°C, drain voltage (VDD) = 5 V, and quiescent drain current (IDQ) = 600 mA for nominal operation, unless otherwise noted.
Table 1. Parameter Symbol Min Typ Max Unit Test Conditions/Comments FREQUENCY RANGE 20 34 GHz GAIN 15 17 dB
Gain Flatness ±0.5 dB Gain Variation over Temperature 0.012 dB/°C
NOISE FIGURE 6 dB RETURN LOSS
Input 20 dB Output 20 dB
OUTPUT Output Power for 1 dB Compression P1dB 26 28.5 dBm Saturated Output Power PSAT 30 dBm Output Third-Order Intercept IP3 40 dBm Measurement taken at output power (POUT) per
tone = 14 dBm SUPPLY
Quiescent Drain Current IDQ 600 mA Adjust VGG1 between −1.5 V to 0 V to achieve the desired IDQ
Drain Voltage VDD 4 5 V
34 GHz TO 44 GHz FREQUENCY RANGE TA = 25°C, VDD = 5 V, and IDQ = 600 mA for nominal operation, unless otherwise noted.
Table 2. Parameter Symbol Min Typ Max Unit Test Conditions/Comments FREQUENCY RANGE 34 44 GHz GAIN 12 15 dB
Gain Flatness ±0.7 dB Gain Variation over Temperature 0.024 dB/°C
NOISE FIGURE 5 dB RETURN LOSS
Input 25 dB Output 16 dB
OUTPUT Output Power for 1 dB Compression P1dB 25 28 dBm Saturated Output Power PSAT 28.5 dBm Output Third-Order Intercept IP3 40 dBm Measurement taken at POUT per tone = 14 dBm
SUPPLY Quiescent Drain Current IDQ 600 mA Adjust VGG1 between −1.5 V to 0 V to achieve the
ABSOLUTE MAXIMUM RATINGS Table 3. Parameter Rating VDDx 6.0 V VGG1 −1.6 V to 0 V RF Input Power (RFIN) 25 dBm Continuous Power Dissipation (PDISS),
TA = 85°C (Derate 75.2 mW/°C above 85°C)
6.77 W
Temperature Storage Range −65°C to +150°C Operating Range −55°C to +85°C Nominal Junction (TA = 85°C, VDD = 5 V,
IDQ = 600 mA) 124.9°C
Junction to Maintain 1,000,000 Hour Mean Time to Failure (MTTF)
175°C
Electrostatic Discharge (ESD) Sensitivity Human Body Model (HBM) Class 1A (passed 500 V)
Stresses at or above those listed under Absolute Maximum Ratings may cause permanent damage to the product. This is a stress rating only; functional operation of the product at these or any other conditions above those indicated in the operational section of this specification is not implied. Operation beyond the maximum operating conditions for extended periods may affect product reliability.
THERMAL RESISTANCE Thermal performance is directly linked to system design and operating environment. Careful attention to printed circuit board (PCB) thermal design is required.
θJC is the channel to case thermal resistance, channel to bottom of die.
Table 4. Thermal Resistance Package Type θJC Unit C-22-31 13.3 °C/W 1 θJC was determined by simulation under the following conditions: the heat
transfer is due solely to thermal conduction from the channel through the ground pad to the PCB, and the ground pad is held constant at the operating temperature of 85°C.
NOTES1. DNB = DO NOT BOND. THESE PADS ARE NOT BONDED.
RFOUT
GND
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2
V DD
1B
DN
B
DN
B
V DD
3B
V DET
22
2 4 7
1619
3 5 6 9 10
11
1314171821 20
8
15
1 12ADPA7002CHIPTOP VIEW
(CIRCUIT SIDE)
Figure 2. Pad Configuration
Table 5. Pad Function Descriptions Pad No. Mnemonic Description 1 RFIN RF Signal Input. This pad is ac-coupled and matched to 50 Ω. 2, 4, 7, 9, 14, 16, 19, 21 DNB Do Not Bond. These pads are not bonded. 3 VGG1A Gate Control for the Amplifier. VGG1A is used with the alternate assembly configuration. External
bypass capacitors of 4.7 µF and 0.01 µF are required (see Figure 57). 5, 6, 8 VDD1A, VDD2A, VDD3A Drain Biases for the Amplifier. VDD1A, VDD2A, VDD3A, are used with the alternate assembly
configuration. External bypass capacitors of 4.7 µF and 0.01 µF are required (see Figure 57). 10 VREF Reference Diode for Temperature Compensation of VDET RF Output Power Measurements. 11, 22, Die Bottom GND Grounds. These pads and the die bottom must be connected to RF and dc ground. 12 RFOUT RF Signal Output. This pad is ac-coupled and matched to 50 Ω. 13 VDET Detector Diode to Measure RF Output Power. Output power detection via this pad requires
the application of a dc bias voltage through an external series resistor. Used in combination with the VREF pad, the difference voltage (VREF − VDET) is a temperature compensated dc voltage that is proportional to the RF output power.
15, 17, 18 VDD1B, VDD2B, VDD3B Drain Biases for the Amplifier. External bypass capacitors of 4.7 µF and 0.01 µF are required (see Figure 53).
20 VGG1B Gate Control for the Amplifier. External bypass capacitors of 4.7 µF and 0.01 µF are required (see Figure 53).
CONSTANT DRAIN CURRENT (IDD) OPERATION TA = 25°C, VDD = 5 V, IDD setpoint = 800 mA for nominal operation, unless otherwise noted. Figure 48 through Figure 51 are biased with the HMC980LP4E active bias controller. See the Biasing the ADPA7002CHIP with the HMC980LP4E section for biasing details.
32
24
26
28
30
10
12
14
16
18
22
20
OU
TPU
T P1
dB (d
Bm
)
FREQUENCY (GHz)
+85°C+25°C–55°C
20 30 32 34 36 3822 24 26 28 40 42 44
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Figure 48. Output P1dB vs. Frequency for Various Temperatures, Data Measured with Constant IDD
THEORY OF OPERATION The architecture of the ADPA7002CHIP, a medium power amplifier, is shown in Figure 52. The ADPA7002CHIP uses a cascaded, three-stage amplifier operating in quadrature between two 90° hybrids.
The input signal is evenly divided into two. Each input signal is amplified through three independent gain stages and the amplified signals are combined at the output. This balanced amplifier approach creates an amplifier with a combined gain of 15 dB and a PSAT value of 30 dBm.
A portion of the RF output signal is directionally coupled to a diode to detect the RF output power (see Figure 52). When the diode is dc biased, the diode rectifies the RF power and makes the RF power available for measurement as a dc voltage at the
VDET pin. Temperature compensation is accomplished by referencing a symmetrical diode circuit that is not coupled to the RF output that contains a dc voltage output, at the VREF pin as shown in Figure 56. The difference of VREF − VDET provides a temperature compensated signal that is proportional to the RF output.
The 90° hybrids ensure that the input and output return losses are >12 dB. See the application circuits in Figure 53 and Figure 54 for further details on biasing the various blocks.
To obtain optimal performance from the ADPA7002CHIP and avoid damaging the device, follow the recommended biasing sequences described in the Biasing Procedures section.
ALTERNATE ASSEMBLY DIAGRAM The ADPA7002CHIP die is symmetric and can be biased from either the north side or the south side (see Figure 57) with equivalent performance.
BIASING PROCEDURES The ADPA7002CHIP is a GaAs, pHEMT, MMIC power amplifier. Capacitive bypassing is required for all VGGxx and VDDxx pads (see Figure 54). Figure 53 shows the internal connections of the bypass capacitors.
VGG1A and VGG1B are the gate bias pads (see Figure 55). VDD1A and VDD1B are the drain bias pads for the first stage, VDD2A and VDD2B are the drain bias pad for the second stage, and VDD3A and VDD3B are drain bias pads for the third stage (see Figure 55).
All measurements for this device are taken using the typical application circuit (see Figure 54) and configured as shown in the assembly diagram (see Figure 53).
Adhere to the following bias sequence during power-up:
1. Connect GND to RF and dc ground. 2. Set the VGGxA or VGGxB voltage to −1.5 V. 3. Set all drain bias voltages, VDDxA or VDDxB = 5 V. 4. Increase the gate bias voltage to achieve IDQ = 600 mA. 5. Apply the RF signal.
Adhere to the following bias sequence during power-down:
1. Turn off the RF signal. 2. Decrease the VGG1A or VGG1B voltage to −1.5 V to achieve
IDQ = 0 mA (approximately). 3. Decrease all VDDxA or VDDxB drain bias voltages to 0 V. 4. Decrease the VGGxA or VGGxB voltage to 0 V. Simplified bias pad connections to dedicated gain stages are shown in Figure 54. Table 6. Power Selection Table1, 2
IDQ (mA)
Gain (dB)
P1dB (dBm)
Output IP3 (dBm)
PDISS (W) VGG1 (V)
600 17.2 30.04 40.6 3 −0.73 700 17.7 30.24 38.7 3.5 −0.67 800 18.0 30.25 37.0 4 −0.62 1 Data taken at the following nominal bias conditions: VDD = 5 V, TA = 25°C. 2 Adjust VGG1 from −1.5 V to 0 V to achieve the desired drain current.
The VDD = 5 V and IDQ = 600 mA recommended bias conditions are to optimize overall performance. Unless otherwise noted, the data shown in the Typical Performance Characteristics section is taken using the recommended bias conditions. Operating the ADPA7002CHIP at different bias conditions can provide performance that differs from what is shown in Table 1 and Table 2. Table 6 shows how gain, OP1dB, and OIP3 vary with the bias current at 34 GHz.
BIASING THE ADPA7002CHIP WITH THE HMC980LP4E The HMC980LP4E is an active bias controller that is designed to meet the bias requirement for depletion mode amplifiers like the ADPA7002CHIP. The HMC980LP4E provides constant current biasing over temperature and device to device variation.
Additionally, the HMC980LP4E properly sequences gate and drain voltages to ensure safe amplifier operation, and offers self protection in the event of a short circuit. The active bias controller
contains an internal charge pump that generates negative voltage that is needed for the ADPA7002CHIP gate and that can also be used as an external negative voltage source.
For more information regarding the usage of HMC980LP4E, refer to the HMC980LP4E data sheet and the AN-1363 application note.
VDD
CP_
VDD
CP_
OU
T
VDIG
VREF
VNEG
FB
VGA
TEFB
FIXB
IAS
ALM
H
ISET
ALM
L
ISEN
S
TRIG
0
VDD
S0
S1
EN
ALM
VDRAIN
VDRAIN
VGATE
GATECONTROL
VNEG
VG2
VG2_CONT
PACKAGEBASE
HMC980LP4E
CONTROLBLOCK
BAND GAP
NEGATIVEVOLTAGE
GENERATOR
GND
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1
1
2
3
4
5
6
18
17
16
15
14
13
7 8 9 10 11 12
23 22 21 20 1924
Figure 58. Functional Diagram of HMC980LP4E
Application Circuit Setup
Figure 59 shows a schematic of an application circuit of the HMC980LP4E used with the ADPA7002CHIP biased at 920 mA. In this circuit, the negative gate control voltage is generated by HMC980LP4E. Figure 60 shows an application circuit using an external negative supply.
In the application circuit, the ADPA7002CHIP drain voltage and drain current are set by the following equations:
VDRAIN = VDD − (IDRAIN × 0.85 Ω)
VDRAIN = 5.78 V − (920 mA × 0.85 Ω)
VDRAIN = 5 V
and
IDRAIN = (150 Ω)/(R10)
IDRAIN = (150 Ω)/(163 Ω)
IDRAIN = 0.920 A
where: VDD is the supply voltage to the HMC980LP4E. IDRAIN is the output current from Pin 17 and Pin 18 on the HMC980LP4E. In this example, an IDRAIN setpoint of 920 mA was chosen. The IDRAIN setpoint must be set high enough to ensure that the desired output P1dB and the maximum RF output power levels can be reached (see Figure 30 through Figure 37 for the relationship between the drain current and the RF output power at various frequencies). The performance of this circuit is shown in Figure 63 to Figure 66.
Limiting VGATE to Meet ADPA7002CHIP VGGx AMR Requirement
When using the ADPA7002CHIP with the HMC980LP4E, limit the minimum voltages for VNEG and VGATE to −1.5 V to keep the voltages within the absolute maximum ratings (AMR) limit for
the ADPA7002CHIP VGGx pad. This is accomplished by setting the R15 resistor and the R16 resistor to the values shown in Figure 59 and Figure 60. Refer to the AN-1363 application note for more information and calculations for R15 and R16.
VDRAIN
VGATE
HMC980LP4E
VDD
S0
VDIG
CP_
OU
T
ISEN
SE
TRIG
OU
TC2
10nF
C2100pF
C14.7µF
C510nF
C44.7µF
VDIG3.3V TO 5V
VDRAIN
VNEG
R11301Ω
R12301Ω
R134.7kΩ
R1410kΩ
VDD
S1
CP_
VDD
EN
ISET
ALM
L
ALM
H
FIXB
IAS
VREF
VNEG
FB
VGA
TEFB
ALM
VG2
VG2_CONT
C61µF
D1 C610µF
EN
VDD5.78V
C9100pF
C74.7µF
C81000pF
C10100pF
C131000pF
C12100pF
C11100pF
C144.7µF
R10163Ω
VDRAIN = 5V
VGATE
R15681kΩ
R16464kΩ
IDRAIN = 920mA
VDD1BVGG1B VDD2B VDD3B
1
2
3
4
5
6
18
17
16
15
14
13
7 8 9 10 11 12
23 22 21 20 1924
DUALSCHOTTKY
RFOUTRFIN
ADPA7002CHIP
GND
VDET
VREF
VDD1BVGG1B VDD2B VDD3B
VDD1AVGG1A VDD2A VDD3A
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Figure 59. Application Circuit Using the HMC980LP4E with the ADPA7002CHIP
VDRAIN
VGATE
HMC980LP4E
VDD
S0
VDIG
CP_
OU
T
ISEN
SE
TRIG
OU
T
C210nF
C3100pF
C14.7µF
C510nF
C44.7µF
VDIG3.3V VNEG
–1.5V
VDRAIN
VNEG
R11301Ω
R12301Ω
R134.7kΩ
R1410kΩ
VDD
S1
CP_
VDD
EN
ISET
ALM
L
ALM
H
FIXB
IAS
VREF
VNEG
FB
VGA
TEFB
ALM
VG2
VG2_CONT
EN
VDD5.78V
C9100pF
C74.7µF
C81000pF
C10100pF
C131000pF
C12100pF
C11100pF
C144.7µF
R10163Ω
VDRAIN = 5V
VGATE
R15681kΩ
R16464kΩ
IDRAIN = 920mA
VDD1BVGG1B VDD2B VDD3B
1
2
3
4
5
6
18
17
16
15
14
13
7 8 9 10 11 12
23 22 21 20 1924
RFOUTRFIN
ADPA7002CHIP
GND
VDET
VREF
VDD1BVGG1B VDD2B VDD3B
VDD1AVGG1A VDD2A VDD3A
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9
Figure 60. Application Circuit Using the HMC980LP4E with the ADPA7002CHIP as an External Negative Voltage Source
Proper dc supply sequencing is required to prevent damage to HMC980LP4E. Adhere to the following power-up sequence steps:
1. Set VDIG, the voltage supply input (Pin 9) for the HMC980LP4E digital circuit (see Figure 60) to 3.3 V.
2. Set S0, the digital control pin (Pin 3) that sets the internal field effect transistor (FET) and the internal HMC980LP4E resistor (RDS) resistance (see Figure 60) to 3.3 V.
3. Set the VDD pin to 5.78 V. 4. Set VNEG to −1.5 V. This step is not needed if using
internally generated voltage. 5. Set the EN pad to 3.3 V. Transitioning from 0 V to 3.3 V
turns on the VGATE and VDRAIN pads.
Adhere to the following power-down sequence steps:
1. Set the EN pad to 0 V. Transitioning from 3.3 V to 0 V turns off the VDRAIN and VGATE pads.
2. Set VNEG to 0 V. This step is not required if using internally generated voltage.
3. Set the VDD pin to 0 V. 4. Set S0 to 0 V. 5. Set VDIG to 0 V.
When the HMC980LP4E bias control circuit has been set up, the ADPA7002CHIP bias can be toggled on and off by applying 3.3 V or 0 V to the EN pad. If EN is set to +3.3 V, VGATE drops to −1.5 V and VDRAIN is turned on at +5 V. VGATE rises in voltage until IDRAIN equals 920 mA. The closed control loop then regulates IDRAIN at 920 mA. When the EN pad equals 0 V, VGATE is automatically set to −1.5 V and VDRAIN is set to 0 V (see Figure 61 and Figure 62).
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3
CH1 2.00V CH2 1.00VCH3 2.00V CH4 2.00V
M20.0ms A CH1 1.12V
31
VDD
VDRAIN
EN
VGATE
Figure 61. Turn On—HMC980LP4E Outputs to the ADPA7002CHIP
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4
CH1 2.00V CH2 1.00VCH3 2.00V CH4 2.00V
M20.0ms A CH1 1.12V
31
VDD
VDRAIN
EN
VGATE
Figure 62. Turn Off—HMC980LP4E Outputs to the ADPA7002CHIP
Constant Drain Current Bias vs. Constant Gate Voltage Bias
The HMC980LP4E uses closed-loop feedback to continuously adjust VGATE to maintain a constant drain current bias over dc supply variation, temperature and part to part variation. Constant drain current bias is an excellent method for reducing time in calibration procedures and to maintain consistent performance over time.
In comparison to a constant gate voltage bias, where the current increases when the RF power is applied, this constant drain current circuit example has a slightly lower output P1dB. This effect can be seen in Figure 66. RF performance is lower for the constant drain current bias due to the drain current being lower at high input power levels.
The output P1dB for the constant drain current bias can increase if the bias current setpoint is increased. By increasing the bias current, the output P1dB increases up to the RF drive in the constant gate voltage bias condition shown in Figure 64. The trade-off with this approach is that this higher drain current is present for all RF input and output power levels
The current and temperature limit of IDD under the constant current operation is usually set by the thermal limitations found in Table 3 in the Absolute Maximum Ratings section along with the maximum power dissipation specification. Increasing the IDD does not indefinitely increase the output P1dB as the power dissipation increases. Therefore, consider the trade-off between power dissipation and output P1dB performance when using constant drain current bias.
MOUNTING AND BONDING TECHNIQUES FOR MILLIMETER WAVE GAAS MMICS Attach the die directly to the ground plane with conductive epoxy (see the Handling Precautions section, Mounting section, and Wire Bonding section for instructions).
Microstrip, 50 Ω transmission lines on 0.127 mm (5 mil) thick alumina, thin film substrates are recommended to send the RF to and from the chip. Raise the die 0.075 mm (3 mil) to ensure that the surface of the die is coplanar with the surface of the substrate.
Place the microstrip substrates as close to the die as possible to minimize ribbon bond length. Typical die to substrate spacing is 0.076 mm to 0.152 mm (3 mil to 6 mil). To ensure wideband matching, a 15 fF capacitive stub is recommended to be placed on the PCB board before the ribbon bond. See Figure 67 and Figure 68 for details.
MMIC
PCB
50ΩTRANSMISSION LINE
MATCHING STUB/BOND PADSHUNT CAPACITANCE = 15fF
3mil GOLDRIBBON
3mil GAP
RFIN
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6
Figure 67. High Frequency Input Wideband Matching
MMIC
PCB
50ΩTRANSMISSION LINE
MATCHING STUB/BOND PADSHUNT CAPACITANCE = 15fF
3mil GAP
RFOUT
3mil GOLDRIBBON
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7
Figure 68. High Frequency Output Wideband Matching
Handling Precautions
To avoid permanent damage to the die, follow these storage, cleanliness, static sensitivity, transient, and general handling precautions:
• Place all bare die in either waffle or gel-based ESD protective containers and then seal the die in an ESD protective bag for shipment. After the sealed ESD protective bag is opened, store all die in a dry nitrogen environment.
• Handle the chips in a clean environment. Do not attempt to clean the chip using liquid cleaning systems.
• Follow ESD precautions to protect against ESD strikes. • When the bias is applied, suppress instrument and bias
supply transients. Use a shielded signal and bias cables to minimize inductive pickup.
• Handle the chip along the edges with a vacuum collet or with a sharp pair of tweezers. The chip surface has fragile air bridges and must not be touched with a vacuum collet, tweezers, or fingers.
Mounting
Before the epoxy die is attached to the ADPA7002CHIP, apply a minimum amount of epoxy (must order separately) to the mounting surface so that a thin epoxy fillet is observed around the perimeter of the chip after it is placed into position. Cure the epoxy per the schedule of the manufacturer.
Wire Bonding
RF bonds made with 0.003 inch × 0.0005 inch gold ribbon are recommended to be used with the RF ports. These bonds must be thermosonically bonded with a force between 40 g to 60 g. DC bonds of 0.001 inch (0.025 mm) in diameter, thermosonically bonded, are recommended for bond wire connections. Create ball bonds with a force between 40 g to 50 g, and wedge bonds with a force between 18 g to 22 g. Create all bonds with a nominal stage temperature of 150°C. Apply a minimum amount of ultrasonic energy to achieve reliable bonds. Keep all bonds as short as possible, less than 12 mil (0.31 mm).
Alternatively, short (≤3 mil) RF bonds made with two 1 mil wires can be used in place of the gold ribbon.
ORDERING GUIDE Model1 Temperature Range Package Description Package Option ADPA7002CHIP −55°C to +85°C 22-Pad Bare Die [CHIP] C-22-3 ADPA7002C-KIT −55°C to +85°C 22-Pad Bare Die [CHIP] C-22-3 1 The ADPA7002C-KIT is a sample order of two devices.